A clock splitter device for forming a clock/inverted clock signal pair. The input clock signal is sent through an initial buffer stage and applied to two parts of a second stage. The second stage includes a single stage buffer and constricted inverter to provide two inverted outputs. The transistor arrangement of these two parts provides an equal delay to the two signal paths. The outputs of these two parts are sent to identical output buffers. Because the two paths have identical transistor delays, and since the metal paths on the board are arranged to have identical delays, the two paths can very low skew therebetween.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A clock splitter, comprising: an input buffer for receiving an input clock signal; a non-inverting single stage buffer, the single stage buffer having a limited output voltage swing; a constricted inverter having an output inverted voltage swing constricted substantially to a same range as the output voltage swing; an output of the input buffer provided as an input to both the single stage buffer and the constricted inverter; a first output buffer and a second output buffer, the first output buffer having an input coupled to an output of the single stage buffer, and the second output buffer having an input coupled to an output of the constricted inverter.
2. The clock splitter according to claim 1 , wherein an output clock signal is formed at the output of the first output buffer and an output inverted clock signal is formed at an output of the second output buffer, the output clock signal and the output inverted clock signal having substantially zeroed skew with respect to each other.
3. The clock splitter according to claim 1 , wherein the input buffer, the first output buffer and the second output buffer are CMOS Inverters.
4. The clock splitter according to claim 1 , wherein the single stage buffer includes an NMOS device coupled to VCC and a PMOS device coupled to VSS to produce a non-inverting output.
5. A clock splitter comprising: an input buffer for receiving an input clock signal; a single stage buffer: a constricted inverter, an output of the input buffer forming an input to both the single stage buffer and the constricted inverter; a first output buffer and a second output buffer, the first output buffer having an input coupled to an output of the single stage buffer, and the second output buffer having an input coupled to an output of the constricted inverter; wherein the constricted inverter includes a first PMOS device coupled to VCC and a first NMOS device coupled to VSS, and a second NMOS device coupled to the first PMOS device and a second PMOS device coupled to the first NMOS device.
6. The clock splitter according to claim 1 , wherein the input buffer, single stage buffer, constricted inverter and first and second output buffer are formed of PMOS and NMOS transistors which are sized relative to each other to give equal rise and fall edge rates.
7. The clock splitter according to claim 1 , wherein metal traces in the signal paths through the clock splitter, of the clock and inverted clock signals, are matched in length and area so as to produce substantially equal delays.
8. A method of making a clock splitter, comprising: providing a non-inverting single stage buffer, the single stage buffer having a limited output voltage swing; providing a constricted inverter having an output inverted voltage swing constricted substantially to a same range as the output voltage swing; providing substantially matched transistors in the single stage buffer and the constricted inverter to produce equal rise and fall edge rates and to match a delay time within the single state buffer with a delay time in the constricted inverter; providing substantially matched metal trace lengths so as to produce substantially similar delays in signal paths for outputs from the single stage buffer and the constricted inverter.
9. The method according to claim 8 , further comprising: providing an input buffer for receiving an input clock signal and providing a common clock signal to the single stage buffer and constricted inverter.
10. The method according to claim 8 , further comprising: providing a first output buffer and a second output buffer, the first output buffer receiving an output from the single stage buffer and the second output buffer receiving an output from the constricted inverter.
11. The method according to claim 8 , wherein the single stage buffer includes an NMOS device coupled to VCC and a PMOS device coupled to VSS.
12. A method of making a clock splitter, comprising; providing a single stage buffer and a constricted inverter; providing substantially matched transistors in the single stage buffer and the constricted inverter to produce equal rise and fall edge rates and to match a delay time within the single state buffer with a delay time in the constricted inverter; providing substantially matched metal trace lengths so as to produce substantially similar delays in signal paths for outputs from the single stage buffer and the constricted inverter; wherein the constricted inverter includes a first PMOS device coupled to VCC, a first NMOS device coupled to VSS, a second NMOS device coupled to the first PMOS device and a second PMOS device coupled to the first NMOS device.
13. A clock splitter apparatus comprising: a non-inverting single stage buffer, the single stage buffer having a limited output voltage swing; a constricted inverter having an output inverted voltage swing constricted substantially to a same range as the output voltage swing; a first input to provide an input clock signal to both the single stage buffer and the constricted inverter; a clock output coupled to the output of the single stage buffer to provide an output point for a clock output signal; and an inverted clock output coupled to an output of the constricted inverter to provide an output point for a clock inverted output signal.
14. The clock splitter apparatus according to claim 13 , wherein the dock output signal and the inverted clock output signal have substantially zeroed skew with respect to each other.
15. The clock splitter apparatus according to claim 13 , wherein the single stage buffer and constricted inverter include PMOS and NMOS transistors which are sized in regard to each other to give equal rise and fall edge rates, and which cause similar delay times in the single stage buffer and the constricted inverter so as to produce substantially zeroed skew.
16. The clock splitter according to claim 13 , wherein the single stage buffer includes an NMOS device coupled to VCC and a PMOS device coupled to VSS.
17. A clock splitter comprising: a single stage buffer; a constricted inverter; a first input to provide an input clock signal to both the single stage buffer and the constricted inverter; a clock output coupled to the output of the single stage buffer to provide an output point for a clock output signal; and an inverted clock output coupled to an output of the constricted inverter to provide an output point for a clock inverted output signal; wherein the constricted inverter includes a first PMOS device coupled to VCC, a first NMOS device coupled to VSS, a second NMOS device coupled to the first PMOS device and a second PMOS device coupled to the first NMOS device.
18. The clock splitter according to claim 13 , further comprising: a first output buffer and a second output buffer, the first output buffer receiving the output of the single stage buffer and having an output coupled as the clock output; said second output buffer having an input coupled to the output of the constricted inverter and an output coupled as the inverted clock output.
19. A clock splitter according to claim 13 , further comprising an input buffer to receive the input clock signal and to produce an output coupled to the input of both the single stage buffer and constricted inverter.
20. A method of producing a clock/inverted clock signal pair, comprising: providing a non-inverting first part to produce a clock output signal, the first part having a limited output voltage swing; providing a constricting/inverting second part to produce an inverted clock output signal, the second part having an output inverted voltage swing constricted substantially to a same range as the output voltage swing; delaying the clock output signal and the inverted clock output signal equally in the first and second parts by providing matched transistors in the first part and the second part; delaying the clock output signal and the inverted clock output signal substantially equally in signal paths leading through the first part and the second part by matching signal path lengths and areas; and with the clock output signal and the inverted clock output signal having substantially zeroed skew in relation to each other.
21. The method according to claim 20 , further comprising: providing an input buffer for receiving an input clock signal and providing a common clock signal to the first part and the second part.
22. The clock splitter according to claim 1 , wherein the constricted inverter includes a first PMOS device coupled to VCC and a first NMOS device coupled to VSS, and a second NMOS device coupled to the first PMOS device and a second PMOS device coupled to the first NMOS device.
23. The method according to claim 8 , wherein the constricted inverter includes a first PMOS device coupled to VCC, a first NMOS device coupled to VSS, a second NMOS device coupled to the first PMOS device and a second PMOS device coupled to the first NMOS device.
24. The clock splitter according to claim 13 , wherein the constricted inverter includes a first PMOS device coupled to VCC, a first NMOS device coupled to VSS, a second NMOS device coupled to the first PMOS device and a second PMOS device coupled to the first NMOS device.
25. An integrated circuit comprising: a clock splitter, comprising: an input buffer for receiving an input clock signal; a non-inverting single stage buffer, the single stage buffer having a limited output voltage swing; a constricted inverter having an output inverted voltage swing constricted substantially to a same range as the output voltage swing; an output of the input buffer provided as an input to both the single stage buffer and the constricted inverter; a first output buffer and a second output buffer, the first output buffer having an input coupled to an output of the single stage buffer, and the second output buffer having an input coupled to an output of the constricted inverter.
26. The integrated circuit according to claim 25 , wherein an output clock signal is formed at the output of the first output buffer and an output inverted clock signal is formed at an output of the second output buffer, the output clock signal and the output inverted clock signal having substantially zeroed skew with respect to each other.
27. The integrated circuit according to claim 25 , wherein the constricted inverter includes a first PMOS device coupled to VCC and a first NMOS device coupled to VSS, and a second NMOS device coupled to the first PMOS device and a second PMOS device coupled to the first NMOS device.
28. The integrated circuit according to claim 25 , wherein metal traces in the signal paths through the clock splitter, of the clock and inverted clock signals, are matched in length and area so as to produce substantially equal delays.
29. An electronic device comprising: a clock splitter, comprising: an input buffer for receiving an input clock signal; a non-inverting single stage buffer, the single stage buffer having a limited output voltage swing; a constricted inverter having an output inverted voltage swing constricted substantially to a same range as the output voltage swing; an output of the input buffer provided as an input to both the single stage buffer and the constricted inverter; a first output buffer and a second output buffer, the first output buffer having an input coupled to an output of the single stage buffer, and the second output buffer having an input coupled to an output of the constricted inverter.
30. The electronic device according to claim 29 , wherein an output clock signal is formed at the output of the first output buffer and an output inverted clock signal is formed at an output of the second output buffer, the output clock signal and the output inverted clock signal having substantially zeroed skew with respect to each other.
31. The electronic device according to claim 29 , wherein the constricted inverter includes a first PMOS device coupled to VCC and a first NMOS device coupled to VSS, and a second NMOS device coupled to the first PMOS device and a second PMOS device coupled to the first NMOS device.
32. The electronic device according to claim 29 , wherein metal traces in the signal paths through the clock splitter, of the clock and inverted clock signals, are matched in length and area so as to produce substantially equal delays.
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March 30, 2001
October 15, 2002
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